Phase converting system



Feb. 3, 1948. B. BEDFORD 2,435,189

PHASE CONVERTING SYSTEM Original Filed June 12, 1944 2 Shgets-Sheet 1 Inventor I Burnice D. Bedford,

His Afitorneu Feb. 3, 1948. B. D. BEDFORQD 2,435,139

PHAS-E CONVERTING SYSTEM Original Filed June 12, 1944 2 ee 2 Inventor 2 Burriice Bedford,

by MW His Atbor-neg Patented Feb. 3, 1948 2,4 ,189 PHASE eo vER'rrnG s rs rmu Burnice D. Redford, Scotia, N. Y., assignor to General Electric Company, a QQEPQQQQQ} of New York Original application June 12, 1944, Serial No.

539, 942. Divided and this app 5, 1946, Serial No. 652,168

My invention relates to phase converting sys tems and more particularly to phase converting systems for electronic power conversion anpararent circuits.

This application is a division of my application Serial No.539;942,"file'd June 12, 1944;, entitled converter and assigne dto the asp en appl c tio I i' ust'1f e invention, I will describe it s applied to "an elec'tronic converter 'of th'edual conversion type wherein alternating cur- :t' rectified by anle'ctronic converter to direct current "and" then r'ecjonVert'ed by a second electronic converter from 'direct current to altern t'n f mr t y H Since electronic converter apparatus of the dual' o my "sin type nvert/e both rectification andinv' accurate firin'g'bi 'each tube of the inverteris ssential and in al'revelsible power flow t' as here described; either group" of tubes fat the respect'iye oi the system 'may have to onerate'a's an inverter. Hence; such asy'stem refienible, aecur quickly responsive nae nv tin tem w h t un compli eatiqas a'nd' lsb' 9 m et e or r n ext nfiion C9 which can eff c he i us phase chan es r quired r rec fi Q inve e r io A syst m h v n hes ne a qu fi ati n .5 de cr bed and la e in an pp ication of, Q. Willis, Serial No. 539,842, filed June 12, 1944;; now Patent'No. 2,419,466 Of Apri122, 194'1, and assigned to the assignee of the present application." My invention, generally speaking, is directed to""vari'ous'modifications and improvements in the'phase converter system disclosed in the above iden'tified 'Willis application. ""Itis, therefore, an object of my invention to provide 'a new and'in'oproyed phase converter system for electronic power conversion appara le s It is another object of my invention to provide a ne andirnproved phase converter system for electronic power conversion apparatus to inset one or more of the"severalrequirenients enumer a 'd aboije, depending upon the function "to be med bythecohversio n apparatus.' i 1 a'furth ji Qbict ofmy invention to prow and improvedco'ntrol and phasejcon er, s'ystem' of application or/fof ar ariamvlicanen 'wit elctronic'conversion ap- Y- n ent n wil e b tter unde s ood item w en: sentine taken i -c nec ier cation March a 2 wit t e aetqmpany ng dra ings a d its s ope wi e. n se t on n e p n d. la ms It the s' i 1 and? s l f q eih t a t a at at epre nt tin Q1 1 b dimen of my in en n m am to e plete 'dual cony'ersi ori electronic system, Whereas i Y sA f i fi, wer s we rammes e resen a n of an em q l tnia invention as uti, 'zie'd single 'stepelectro'nic oer r ipi 's' st mi If Y R err nam h drawin and for. the Pr sent tozEiesand 2 onsidere to ther I In ests in an a tern tin current i uit wh ch i v s be nte conne d wi h n. a erna n ur nt 11: Q it I w cons der first t e P w r ci quit and. o facilitate. th descri t on wi l. re bx way o xample t i cuit l s a Q We}? P wer irc t. and the t be, rou s a scqia s jt i srew ib a rest fi rs and; the, tsuit 2 as. a 5, cy le POW??? circuit and the tube groups associated therewith as nv rter i t b underst d AQWW t at th powe 914 121 5, may. be Q any desi ed o er treatment t e sam or Q? d fie u fre: q ncies, and" that-tee ube, groups. as otiated with the p werris l itma be tra ed a ear iifie ts i verter Un s h a umed co di: on of. u t n I havei u trateq n E 1 W9 tub roups 3, and .50 is we a h rran eq for th e pha 1 1. w ve. ectifica ion and w th tubes which are d rees apart. in Ph se In: sition mounted back to back with the cathode of one tube connected to the anodebf another. In Fig. 2, I have illustrated two tube groups 5 and 6 of"- six tubes 'eac'h;?similarly arranged'for three phase full' Wave inversions The tube groups '3'; 4, 5 and 6 are connected alternatelyin serie's'in a direct current loop comprising conductors 3a, 3b, 4a and 4b whicninclude direct current reactors 7' connected in series between each rectifier and inverter. The; alternate arrangement of" the" 25 andfidcycle tube groupjs'in' th d rect-current loop rninirni'z'es the t' 'lt'a e leveland is a feature antecedent: claim United States Letters PatentN o. 2 ,419 A'6 grantednpril 22," 1947, upon; an application-"mfg Schmidt."

'i fit ub fgr; and 4. a e connect d "to an alternating current circuit l integer; transformers l and fiwhich "'are""designe d and connected to obtain multiphase operation. One arrangement which fias'ben found to be satis- WZQ'??? i fi if i fi h t l*? i "5W9 h fi hfl fi seminary wind 91 151 "t bl sp a d item ethe thirty d ree wh h m y b obta ned by. c nn cti a rimer-Immune l as Qe a ed with, econ ary. win n delta ccnnaqt n'a d a primary winding 12 in Y connection associated with secondary winding 10. The inverter type groups and 6 are similarly connected to the alternating current circuit 2 through transformers l3 and [4 having, respectively, Y connected secondary windings l5 and I6 and delta and Y connected primary windings l1 and I8. Between each group of transformer secondary windings and its associated tube group, current limiting reactors l9 and 20 are introduced to limit the fault currents during arc-backs or a short circuit on the direct current loop.

The three-phase double-way (full wave) circuit illustrated is particularly desirable because of its high apparatus economy and good operating characteristics. Although various types of tubes may be used, I have found in practice that of the presently available commercial forms a type known in the art as a pentode ignition is satisfactory for large power commercial use. For the details of this type of tube, reference may be had to U. S. Letters Patent No. 2,209,819, granted July 30, 1940, upon an application of K. H. Kingdon and assigned to the assignee of the present invention. For the purpose of explaining my invention as utilized in the power conversion system illustrated, it will sufiice to refer to one of the pair of tubes of tube group 4 which is to be taken as representative of all of the other tubes. Each tube comprise an anode 2|, a mercury pool type cathode 22, an immersion-ignitor member 23, a holding anode 24 and a control member or grid 25. The immersion-ignitor 23 establishes a cathode spot by conducting a current peak of short duration whereupon an arc is established and maintained by the holding anode 24. The grid 25 is utilized to determine the time of starting conduction between anode and cathode and also reduces the deionization period at the end of conduction.

Before considering the excitation and control means for the several electrodes of the tubes, it may be helpful to consider briefly some of the characteristics of the rectifier and inverter action of tubes. The direct current voltage of the rectifier tube group or an inverter tube group may be varied by grid control. If a represents the angle by which the grids of the rectifier are retarded, the theoretical direct current voltage Edo of the rectifier will be Eao=Eo cos a (1) In inverter operation the grids may be advanced by the angle B and the corresponding theoretical counter emf E"do will be "do=Eo COS B (2) The current-limiting reactors l9 and 20 together with the leakage reactance of the transformers causes a reduction of the direct current voltage when operating a a rectifier and an increase in the direct current counter voltage when operating as an inverter. The direct current voltage change Ex, which is a drop for a rectifier or a rise for an inverter, is given for the three-phase fullwave circuit by the relation E$=vgXuluEo (3) where E0 represents the no load direct current voltage, Xu represents the per unit reactance, and In represents the per unit load current. Correcting the theoretical D.-C. voltage for tube are drop Ea, reactance drop Ex, and for transformer copper losses, the output D.-C. voltage of the rectifier E dc will be Here, Ru represents the per unit transformer resistance. A similar relation for the inverter voltage E 'de is obtained by adding the arc voltage and the resistance and reactance voltages to the theoretical direct current voltage E"do- E cos acos B4 The are drop for high voltage tubes will be of the order of 1% of the load.

Equation 6 shows that the angle of inverter ad- Vance B must be greater than the angle of rectifier retard a. Increasing B or decreasing "a will raise the load. In practice, it is desirable to control a to regulate the load flow to the desired value. In the case of a low voltage on the rectifier side or high voltage on the inverter side, it may be imposssible to obtain the desired load by reducing a to zero. It will then be necessary to transfer the function of load control to the inverter and increase B to obtain the desired load. For normal voltage levels and loads, it is preferable to control the load by the rectifier grids for both directions of power flow, the inverter grids being adjusted to provide ample deionization time. It is known that the grid of a gas tube is not able to gain control (prevent current conduction) until a short interval has elapsed after conduction. Thi interval required for regaining control is known as the deionization time.

The deionization time is of primary consideration in inverter commutation. During the deionization time, the anode of the tube must be held negative to prevent conduction. The duration of the negative anode voltage may exceed the deionization time required by the tube, but the deionization time sets a minimum duration for the negative anode voltage. Commutation in an inverter requires that the next succeeding tube to take over must be fired before its line to neutral voltage equals that of the tube from which current is being commutated. The angle by which the next conducting tube is fired ahead of the tube from which current transfers is called the angle of grid advance 0. The transfer is effected because the counter emf in the phase of the tube taking over is lower than the tube presently conducting. The voltage difference between these two tubes is the commutating voltage. The action is quite similar to commutation in a D.-C. motor when the brushes are shifted against the direction of rotation. If the commutating voltage persists after the current has been transferred to the tube next in order, the remaining commutating voltage will be in a direction to reverse the current through the previously conducting tube and will appear as a negative voltage across this last mentioned tube. During this intervaLthe-previously conducting tube-must dfonize bcau'se after this period a positi 'vevblt= age will be impressed betweeri'the anode 'and cathode of the previously c'on'ducting tube. A loss of control will resultif the previously con ducting tube has not regainedcontrolj It is evident that the angle of grid advance which was represented by 'B in Equation 2 equals the commutating' angle plus the available-deionization t me. Writing this in the form ofan equation where U repre ents the conin'iutatie le and M represents-theavailabledeionization angle of margin ang e Be +1 a tor in commutation. If the AJ-C. voltage drops or the-load increases Withouta corresponding infcrease in the angle B, the margin anglewill be partly absorbed by the greater cdmmutating angle. A large margin angle results in low power ia-ctor operation'so it is desirable to operate with as' small a margin angle as possible." Frdllfi Equation 7 it is evident that the angle of advance B must be increased with load 'tomaintain a -confstantin'ar'gin angle because thefangle of com mutation U will increase with load. Increasing angle B will, however, cause a greater lead as shown "by "Equation Q As a result, it has been found that increasing the inverter load angle, while holding the rectifier grids fiir'ed, result-sin a" largenload with an approximately constant mgrgmangle' v. t I 7.,

In the light of the previous discussion, the phase convert'er system of 'myp esent "invention lllay l'ldw be I cons'iderd vith ahead-appreciation oi the variousdunc'tions involved; gqen a'ny speaking, the rectifier grids should be controlled to inaintain the desired 'load' and the" inverter grids varied with load to maintain a safe mar in angle. When-changingthe'respectivetubegroups "froni'recti'fier to intense operation for reverse power flow, the phas'position of the grid volt} age of therespect'ive tube'gioups must be sh ed by approximately 150 degrees. These rurieu s or that part" of the systernshownin Fig'fl are performed, in accordance with rny' inventiqnphy the phaseshift n'ettvOrkZG and its 'ass oci'ated'cir Power for'boththe gridand ignition circuits of the assumed 60' cycle end' 1s g'jbtaine'd from an j ili ar'y' power I tra1nslziu"r'n'ei'' 21'"Whi'ch'is utilized' o energize an auxiliary powerbusfl-d. The tr'ansformer *21 mayhe connected to the powe'r circuit al as illustrated, or toasuppiysouree correlated .in frequencyand inphase "'w'i-th the power circuit I; Thus, thiee phase' po'vver is delivered "by the bus 21a tolines 28,29 and 30, which -'i turn (are connected through *vaname'i peaance ohces such as saturable reactors 3-! 32'; *33, -"'3"4 and 5, 36 to switching means R and T which may :take the-formof two'six pole contactorswherein :R;signifi;es the rectifier --c0n tactor and I signifies ;the inverter contactor. These contactor's inf ltrodueestheigrid phaseshift necessary forFr'e've'f'smgpOWer'fmw. which will he explained in detail later." Suitable interlocks (not shown) will, of :course, :be utilized to "prevent simultaneous @1051. mg of the R and Icon'tactors. These cont'ac'tors connect the .th'ree-fphas'e A.- C. lines28,*2'9a*rid Eilto the twelve phaseinetworkfilii. "This network zcomprisesla plurality of ihductive windings" ar ran ed diagrammatically: in the-'fofm of a polygon and forzthecil-lustratedrembodinient of mat-urea: tion :compris'es aItWIve-sided polygon consisting er windings identifiedin'a counterclockwise 'order from :the twelve oiclockzposition .as windings 31 to 48,"inc1usive. The junction 'points Qf the windings starting with thetiiv'elve oclo'ck position are identified ina counter-clockwise direction: by the points 49 to 60,-inblusive. Stabilizing :windirigsi='6 f 120 56 interconnect, respectivelyj-the -junc.- tion -poihts l9itoi58 3fl to ;5'1 to 54, i54fit0fi5l, 53 to 50 and 50 to 59. Each of the severalg-r'oum of windings in parallel vphysical relation considei'ed diagrammatically, such as the triplet oft windings 48,66 and 4-2, would he -placed. o'n the same magnetic core (notshownl. 'Each of "the peripheral windings to '48, inclusive, may :be providedwith taps "for" correction of the 'respec tiv excitation circuit but to avoid undue complexity in ithe'd-rawings only those taps required 'fbi" the excitation cireuits illustrated will re ferred tolat'e T e-reactors '31 to 36 are direct current saturated reactq s In accordance with the illufsf tratedeinbodiment oir'ny invention one group '0; aux bias: windings or pres'aturating vii-tidings -51 to l'fare conneetedin seriesrelation each with the same polarity an additive relation n en e'r'gizedfronf anyconveni'ent; relatively constant, D'J 'CI source" 'ivhicm as illustrated, maybe obta'ined from the-bus 21a through a full wave'-recti'fiei "1320f" The v vi'lfidirigs fi'l 12 are associated with the A.-G. react r windings 3;!) to at in-"the same order as the numeralshave been specified and the current direction ass'u'rned is" indicated by meadows associated' with' wind ngs s1 and 1-2. A group ofcontrolsaturatingwindings Q to 18 are connected-'iri' eris}relation but with the oddnumbered'wih ings" of this series re:- versedin polaiity' relati e to the even numbered windings. Due tothe reversal oi the odd nuin} b'ered control-reactors relative to the even, in combination"with" the"presaturated windings, a variation in direct currentthroug'h the control saturating-windings *aifects the "odd and even numberedreactors oppositely. Thus an increase in 'the'co'n'tr'ol turating current increases the saturation of; 'sa theodd'nurnbered reactorsby aidi h fi e W ne W n n ene e rase ,thesatur'ation H th evennurnbered reactors obposififi ih rams Win n e ease decrease-ins gra i g curr'entcauses the reverse effect! e a 'as a pe $3 the mm tween 25 is h mmere -tn be effected in the conventional counterclockw'i" e" d'ijection when the odd rnu n' f beredreactors a' *being'satur'ated 'while the even numbered rea'c s arebeing unsaturated. 'ltliis thus pds's'ibleto s ft theghd through the avail}- able' range of de'grees-by reversingthe current in the control saturating windings although in the particular arrangement utilized emf-t sn f emay-be efiected without "c lirent reversal."For eachvalue of saturating current there a corresponding phasepositioatr thntW'oTkiB. "Shifting the 'fiective' fioint of entry of the sup y conductor 2a," 2a nd '30 to the l2-phase netw'orkby D. saturation sh fts the operating fphas'e' o-f-"th two -6 -t ube "groups '3 and twitho'iit disturbing their IZ-phase relation, and without disturbing the timing at the ignitors,

grids and "holding'anodes for any tube. These control saturatin'g winding 1:, to is are ,ciinfnected to betariabiy nerg'ized'from a controllablesour'ce'oi direct current such asa controllable amqi e' i marine-me es r be is 7 scription of the illustrated embodiment of my invention that for each pair of impedances or saturable reactors the same efiect is produced if the bias or presaturating winding are arranged in opposed relation and the control windings in additive relation. The principle of control is dependent upon effecting an inverse change in the respective impedances of each pair of impedances with a single varying current whether the current in the control winding is in one direction or the other.

If it be assumed that the R contactor is closed (all R switches closed) each of the A.-C. lines 28, 29 and 38 will be connected through the D.-C. saturated reactors to two point on the twelvephase network 26. Thus line 29 is connected through reactor 33 to Junction point 68 in the network and is also connected through reactor 34 to junction point Points 80 and 5| are separated by ninety electrical degrees on this network. In a similar manner, line 28 is connected to points 56 and 59 through reactors 3| and 32, and line 30 is connected to points 52 and 55 through reactors 35 and 36. If the odd numbered reactors 3|, 33 and 35 are fully saturated and the even numbered reactors 32, 34 and 36 are unsaturated, lines 28, 29 and 38 are closely connected to the points 56, 68 and 52. This condition is taken to represent a fully advanced position. Reversing the saturation of the reactors, so that the odd numbered reactors are unsaturated and the even numbered reactors are fully saturated, in effect shifts the points of entry of lines 28, 29 and 38 ninety degrees to points 59, 5| and 55, respectively. This shift in phase of the efiective points of entry in a counterclockwise direction around the network results, in effect, to rotating the network in a clockwise direction and is considered, according to convention. to represent a retardation in phase to the fully retarded position. It is, therefore, evident that the 12-phase network 26 with the R contactor closed can be given a 90-degree phase shift by reversing the saturation of the direct current reactors. When the I contactor is closed (all I switches closed) and the R switches opened, the saturating reactor spans an angle of only about 60 degrees and the grids may be advanced continuously through an angle of the order of 60 degrees beginning at a predetermined angle of advance of the grid voltage for inverter operation. Thi shift in phase for either rectifier or inverter is fairly continuous upon variations in the saturating current in accordance with the principles recited above. The voltage variation of the network 26 need not exceed over a phase shift of 90 degrees, and it has been found that the time required for a complete phase shift of 90 degrees need not exceed 0.1 second for a 60 cycle network. All tube control power for the grids, ignitors and holding anodes for the 60 cycle tube groups 3 and 4 is furnished by the single network 2|3 As previously noted, the variable direct current energization for the control saturating windings of the phase-shift network 26 is obtained from a readily controllable and reversible direct current source of voltage, which is illustrated as a direct current dynamo-electric machine 19. Although various known types of direct current dynamo-electric machines may be utilized to carry out my invention in its general aspects, I have found in practice that a particularly suitable type is the compensated cross-armature reaction excited machine known inthe art as an greatest.

amplidyne generator such as is described and claimed in United States Letters Patent No. 2,227,992, granted January 7, 1941, upon an ap- Plication of E. F. W. Alexanderson and M. A. Edwards and assigned to the assignee of the present application. The machine 19 is, therefore, illustrated with a pair of short circuit brushes 88 for providing the main armature reaction excitation of the machine and a pair of load brushes 82 which are displaced from the short circuit brushe 80. The machine is also provided with a number of control field windings which may be identified by their respective functions as the anti-hunt winding 83, current limit field 88, load transfer field 85 and main control field 86. To facilitate an explanation of the operation of the system, it will be assumed that a positive field terminal to the right, that is, with current flow from right to left (Fig. 1) results in a positive terminal of the left-hand brush 82 of generator 19. This convention is just the opposite in Fig. 2 since that drawing, in so far as the corresponding dynamo-electric machine is concerned, is in effect a mirror image of Fig. 1. The left-hand load circuit brush 82 is connected directly to the terminal windings 13 of the series of saturable reactor control windings 73 to 18. The right-hand load circuit brush 82 is connected through an inductive coupling device 89 and a resistor 90 to the terminal winding of the winding 18 of the saturable reactor control windings.

The anti-hunt circuit of field winding 83 will now be considered. The inductive coupling device 89 is provided with a secondary winding 8| having two end terminals and an intermediate terminal 92. One end terminal of winding 9| is connected directly to one terminal of the antihunt winding 83 and the other end terminal is connected through an R switch 93 to the midpoint of two series connected resistors 98 and 95. These resistors, in turn, have a circuit in shunt thereto and including a contact rectifier 98 poled to pass current in the direction indicated by the arrow. In a similar manner, the intermediate tap 92 is connected through an I switch 9! to the midpoint of two resistors 98 and 99. These resistors, in turn, are provided with a shunt circuit including a contact rectifier I80 poled in a direction to pass current in the direction indicated by the arrow. The R and I switches here, as well as in all other cases in the drawing, are interlocked so that when the R switches are closed the I switches are open and vice versa. The anti-hunt circuit may be better understood by considering the R switch 93 closed and the I switch 91 open. In this case it will be observed that the circuit of field winding 83 may be traced from the right-hand terminal of the winding 9|, considered as a source of positive voltage if the current increases for the polarity of the generator indicated, through the R switch 93 with one path through resistor and another parallel branch path through resistor 94 and rectifier 96, to the left-hand terminal of winding 83 with current through the winding from left to right. Thus the winding 9| picks up a transient voltage as the armature current increases. This voltage is in a direction to energize the anti-hunt field 83 in a direction to make the left-hand brush less positive and thus oppose the change in armature current. If the change is in one direction the current has the two paths traced above and due to the relatively low impedance as contrasted with the one path the anti-hunt efiect is the However, if the change of current is 9. in: the opposite direction or a decrease only the sin le 7 Path" through resistor 95. is avails-rue and due to? the relativ ly ,h gher impe ance the antihunt effect is-less. The arrangement, therefore, plfdvides adjustments for obtainingdifierent antihunti-ng effects, ,depen'dingupon the direction of change. The} same operation is efiected with the I switch closed and the R' switch 93 opened through the're'sis'tors" 98[and.9.9 and the rectifier If. the control generator were tokeep on increas ing its armature current beyond the value of control current or ampere turnsatwhichthe control current eifectwas greater than the bias or presa' t1 .1ratingv current effect, the maximum irnpedance of the desaturat'ed. reactor would, be passed and the impedance thereafter decreased so that the phase shiftwould then start to change inthe opposit direction. In order to accomplish this control, I provide a' reference voltage which is proportional to, the maximum impedance condition of the desaturated reactor which may be a component of voltage proportional to the presaturating current or biasimagnetomotive force and combine this component of voltage with a component of voltage proportional to the control c'urrentof the saturable' reactors. I

In the circuit illustrated the reference con. ponent of voltage for onedi'rection of armature current is derived frorna; resistor I101 connected in series relation with the output circuit of the rectifier l3'which1is aisubstantially constant voltage output; derived from the" circuit of the. pro-'- saturating windings, 6 1'"12. For the reverse directionof armature current the reference cornponent of voltage is deri'ved'ironi a, resistor iilia connected in series with resistor Nil. It will, of course, be understood that any other constant reference voltage may be used v'rithout departing from my invention in its broader aspects if such component of voltage bears the abbveuescribed relation to the maximum impedance condition to the desatura'ted reactor. The variable component of voltage proportionalto the control winding current may be obtained from the armature current of the machine 19 and as illustrated is derived from the resistor-Q0 in the armature circuitof machine'is. The left hand terminal of field winding 8%. is connected to one terminal of resistor Mia through a contact rectifier hi2 which is pol-edin adirection to pass. current in. the directionof the arrowwhen t-h'e'variable cornponent of voltage fromresistor 9B is greater thanthe referencevoltage. The current limit circuit may now be traced from positive terminal of resistor Eil through the resistor lllla, through rectifier U2;to the left-hand terminal of field winding 84, through field winding 84 to the mega" are terminal or resistor 90. The rectifier renders the circuit unidirectional so that there is no current traversing the current limit field at until the component of voltage fromresistor 9i; exceeds the reference component of voltage from resistorlllla. However, withthe assumed polarities it will be noted that when the armature can rent of, machine 78 raises the positive potential or resistor 90 abovethat of the reference potena tialg, field Winding 84' is. energized from left to right which makes the positive brush 82 less positive and, therefore limits'the'armature current.

When the current in the armature of the control generator 19 isin the reverse direction, the voltage component across resistor 9G is in the reverse direction from that assumed above and it is then necessary to select a reference voltage which is also reversed from that previously assumed in order to have the two components opposed. Hence, the resistor IUI is connected in series with the component of voltage across resistor 90 through a contact rectifier IBM. In this case; the current limit circuit may be traced from the left-hand terminal of resistor 9%) (now plus),

a through field winding 24, through rectifier W211,

' from resistor 90 exceeds the reference component armature polarity of the machine it its right h'and brush $2 is now positive and hence aposi tive potential on the right-hand terminal of field winding Mtends to make the brush less positive and thereby limit or reduce the armature current in the reversed direction.

Since consideration of the load transfer field 85 involves a number or devices at the opposite end of the system and illustrated in Fig. 2, such consideration will be deferred until later and the excitation and control of the load control field 86 will now be considered. In principle, when the tube groups 3 and 4 are operated as rectifiers the machine '29, through' the' phase shift circuit 2t, operates as a regulator balancing the load current of the conversion apparatus against a reference voltage or signal. A measure of the load current of the converter is secured by rectifying the output of current transformers connected in the input circuit l to the rectifier. Thus on the previously stated assumption the apparatus of Fig. 1 will be considered as the cycle rectifier end and that of Fig. 2' as the output or 25 cycle inverter end, a component of voltage proportional to the load current is derived from current transformers its; associated with circuit 1. The output of current transformers Hi3 is converted through transformer I94 to an A.C, voltage component and this voltage component is transferred through a group of conductors we to a suitable rectifier let. A resistor lt'l'l is connected across the rectifier Hi6 and is provided with an adjustable tap its to provide aconvenient adjustable. voltage component corresponding to the load current of the converter. This component of voltage may thus be referred to as the load voltage E'L. This component of voltage corresponding to rectie fierload current is arranged to oppose a reference component of voltage whichmay be referred to as ER. The reference voltage En may be obtained rroma suitable adjustable source of constant voltage which remains substantially OOH-.- stant at the adjusted level. In practice, I have found that a'three-phaseinduction regulator I09 having its shunt and series windings connected in a manner to provide a three-phase voltage of adjustable magnitude makes a satisfactory reference Vifltagd; The induction regulator as illustrated is connected to be energized from the bus 27a. The output circuit of the device 69. is

11 connected to a transformer H which is provided with a primary winding III and in order to provide a reference voltage for both ends of the sys tem, two secondary windings H2 and H3, respectively, are also provided. The output voltage of the secondary winding I I2 is connected to a suitable rectifier H4 for use at the 60 cycle end of the system (Fig. 1) and the secondary winding H3 is connected through a group of conductors H to a suitable rectifier H4 for use at the 25 cycle end of the system (Fig. 2). A pair of resistors H5 and III are connected in series across the output of the rectifier H4 and are provided with adjustable taps H8 and H9, respectively, to make available the adjustable reference component of voltage ER, The adjustable contacts I08 of the E1. resistor and H9 of the ER resistor are connected together and provided with a connection terminal I20 which is connected through an I switch I2I to the left-hand terminal of field winding 86. The lower terminal of resistor I01 is connected through an R switch I22 to the lefthand terminal of winding 88. The adjustable contact H8 of the ER resistor is connected through an R switch I23 to the right-hand terminal of winding 86. The energization of winding 86 during rectifier operation of the tube groups 3 and 4 will now be evident. It will be noted. that the reference voltage component ER and the load current voltage component Er. are connected in series opposition across the field winding 86. With the R switches I22 and I23 closed the circuit may be traced from contact I I8, the positive terminal of the reference voltage En through R switch I23, through winding 86 from right to left, through R switch I22, through load current resistor I01, back to the negative terminal H8 of the reference voltage resistor I IT. The difference between thereference voltage En and the load voltage Er. will act on the control field 85. If the load is lower than is desired, the reference voltage En will exceed. the load voltage EL and will excite the field winding 88 from right to left in a direction to change the saturating current of control saturating windings I3 to 18in a direc- 45 reference voltage Ea, the reverse action will take 60 place and the rectifier grids will be retarded.

The induction regulator I09 may be operated in response to several methods of regulating the load such as manual control, watt control or demand watt control. The various novel features involved in these several controls for regulator I09 are described and claimed in United States Letters Patent No. 2,407,072, granted September 3, 1946, upon an application of Gittings and Bateman. For purposes of simplicity, I have shown a manual control which includes, as a suitable driving means for the rotatable element of the device I09, a reversible motor I24 connected through a suitable shaft and gearing I25 to the rotatable element of the induction regulator, As a, means for controlling the direction and amount of rotation of the motor I24 I have shown a reversing switch I26 connected between the motor I24 and a source of voltage I21 indicated by the and signs.

The field winding 86 is controlled-in accordance with the same reference voltage Ea when the tube groups 3 and 4 are operated as inverters, although other variable components of voltage ER across the contacts II8-I I9 of resistors H8 and H1 may be used as illustrated. This reference voltage is connected in series relation with three other voltage components particularly pertinent to inverter operation across the field Winding 86. One of the three components is a voltage component Ep derived from the resistor 99 or a portion thereof as illustrated which is proportional to the armature current of the machine I9. Another component which may be referred to as inverter bias is derived from the voltage of the bus I through the bus 21a, to adjust the initial advance of the inverter grids. A suitable rectifier I28 is connected to the bus 21a and a resistor I29 is connected thereacross and provides a convenient source of D.-C. voltage corresponding to the output voltage of the inverter tube groups 3 and 4 when these tubes are operating as inverters. This component of voltage may be used in an additive direction, as illustrated, to the reference voltage ER. Still another component of voltage is derived from the bus 21a through a negative phase sequence network device I30, the output of which is rectified by a suitable rectifier I3I having a resistor I32 connected thereacross. The component of voltage from resistor I32 is in the same direction as the reference voltage En and is utilized to modify the control in the event of phase unbalance in the inverter output circuit. The lower terminal of resistor I32 is connected to the contact I I8 on the reference voltage resistor through an I switch I33. The energizing circuit for winding 88 during inverter operation will now be evident. Starting with the lefthand terminal of winding 86, the circuit may be traced through I switch I2I. reference resistors II 6--I I I, I switch I 33. negative phase sequence resistor I32, inverter bias resistor I29, armature current resistor 90 and to the right-hand terminal of winding 86. With this circuit just traced, if the reference voltage is higher than the resultant of the other three components of voltage, more load is being indicated and the winding 88 will be energized in a direction from right to left under the assumed polarities and make the lefthand brush 82 more positive to cause the phase shift circuit to advance the inverter Pride. In this way the inverter grids are ad anced to maintain an approximately constant mar in an le or deinniz tion angle, the importance of which was explained above.

The final feature of field contro to be considered is that involving the energiz'ation of winding 85 which is herein referred to as load transfer control. However, since winding 85 is de endent for its energization upon the apparatus shown in Fig. 2, a brief description of that figure n w will aid in a consideration of the load transfer control. Since the v rious elements and devices at the two ends of the system are substantially identical. except for design changes that may be necessitated by two different frequencies. all the elements and devices of Fig. 2. which has been assumed to be at the 25 cycle end: have been given the same reference numerals. with a prime mark, as the corresponding elements and devices of Fig. 1. The only exception to this system of identification is that part of the ma n power circuit which has been previously described.

The mechanism and system of load transfer involving the energization of field winding 85 of generator I9 mav now be considered when the previously considered tube groups 3 and 4 and are related to En. The same reference voltage thus the 60 cycle end is being operated as an inverter tvlth power new irrom circuitl to "circuit *Phe principle employed in the transfer is to derive a voltage component from the "armature current of the -phase shift control generator 1-8 at the now -assume-d rectifier end (Fig. 2), and halance this component of voltage against a ref e'renc'e component of voltageso that field windins 85of gener'at'or 18 (now at the inv'erterend) is energized when the component of voltage cor- 'r'espox'ifdin'g'to the armature current of the control generator at "the rectifier end exceeds the refer ence voltage. The reference voltage may con teni'entl he obtained from the resistor llil 'a which is connected in circuit with the outputnf the presaturating current rectifier 13'p. A com moment of voltage, which is variable in accord ance with the armature current of the control getierator 19 is obtained from the resistor which is connected in series with the load brushes 2-. These two components of voltage areconmooted in a circuit with opposed polarities through 'a'condu'ctor I34 which interconnects the positive terminal of the reference-voltage resistor 101 'a an'd the positive te'mninai of the armaturecurrent resistor 90. A conductor U5 is contietitced to the negative polarity tap HH'b on res'ist'or NI-Pa through an adjustable resistor 1-35, a contact rectifier 1'31 one side of the circuit may traced to the light-hand terminal of winding "85 "of machine 18 (Fig. 1) by way of conductor 135". A conductor I 39" "is connected to the ne at'ive terminal or resistor 90' and may be traced to the lef't hahd terminal of winding "85 '(Fig. 1)-. hence, these two components of voltage "from r'esister -90 and resistor I'D-I'd are c unheated in 'e 'ri'e's opposition and transferred from Fig. 2 to *wir'i'ding'fii on 1 by conductors I35" and +39"; These components of voltage are so related reistive to the direction of conductivity of the rectiher 131' that winding is not energized so long {as the reference voltage from I'U'I 'a is higher than the reference voltage from resistor '98". However, when the current of the now assumed rectifier control generator 79' exceeds a predeter iiiin'ed value, the positive component of voltage from armature current resistor is enabled to send'current in the conducting direction of rec- -tiller 1-31" so a's to send a 'currentthrou'gh winding ii'ffonrright to left and cause the control gen:

crater T9 to advance the phase of the network "tor 19'' of Fig. 2, are identified by unprinted nu inerais.

'Eacli tube of the several tube groups is furhished with appropriate excitation circuit. For the ignitor type or tube a control grid to determine "the instant of conduction in each tube both an ignitor energizing circuit H0 and agrid energizing circuit MI are arranged. for each pair nf tub'e's which are to be conductive 180 degrees apart. For th'e purpose of simplifying the drawing, only one of each of the respective excitation circuits is shown in diagrammatic detail, although lti's to be understood that ignitor and grid cxc'i tuition circuits 'sttidlnlr those illustrated will-he connecte t's-will understood by those skilled the arttctne respectivepairs of valves and to the iprop'eripoint's on the phase "shift network {Hand 26' with due regard to the phase of the anode voltagesor "the particular pair of tubes to 'bvcontrolled. #A suitable arc initiatingcircuit for tubes oftheignitortypaw illustrated, may be of "the so-called magnetic impulse type such as .is described and claimed in United States Letters Patent No. 2;362,=294, granted November 7, 194-4, an aiiplication of A. H. Mittag. This type of i'gnitor circuit is very diagrammatically indi- "cated in Fig.1 and comprises, as part of its principal components, s. firing capacitor I42 and a firing reactorwhich is designed to saturate during 'eachi'half wave oralternatin voltage of the circuit i t0 15y reason of the dischargeof current Irena the firing capacitor 142 through the primary winding "in: transformer I44. The firing circuit may :alsoiinclude a linear reactor Mt connected between the circuit I41! and the firing capacitor 1" to prevent discharge of the capacitance to the'supply circuit and also to limit the current taken'trom the supply circuit at the time the-capacitance discharges through winding '5. insulating transformer, as illustrated, which is providedwith a, ipwii'pfse'condary windings H and is utilized to transform the ignitor peaks unto the voltage level of the tubes. Hence, one'iterm'iliral "of the secondary winding lit-1 is connected to the igni'tor electrode 23 of the upper'righthand tube in tube group '4 thr h a contact rectifier H9, and the other terminal is connected to the cathode 22 of this same tribe. The ignitor oi the opposed tube of this tube pair would :be connected to winding I48 in a similar manner. It is to be understood that the firing peaks *otzfirihg reactor! 43 occur on both the positive and negative half cycles of the source voltage and thus the isingleufirirrg reactor M3 provides tworpeaks "displaced degrees apart so as to serve for firing two opposed tubes.

suitable grid fidnrrg circuit is described and claimed in States Letters Patent No.

241 9365,, granted Ami-1'22, 1947., upon my application; Hen-ca m the system illustrated I have shown the gridfi'emitation circuit quite diagrammatica l'ly but in snflicient detail to incorporate the essentials-features thereof. I again illustrate an insulating transformer Hill comprising a priiirary winding 45! which is connected to the grid icircnitl lflrand 1 pair of secondary wind- 31128152 and 453. 0m: terminal of the secondary winding 1521s connected to the cathode of the upper fight harrd tube of tube group 4. The sec-- ondary winding 2 supplies a potential to the holding anode-circuit 24 through a transformer 45 and to-the rgrid ifi preferably through a peakling transformer iii. ,A suitable bias means, indic'atedahyfthe battery @158, is connected in the grid circuit toholdith'etuhe'ofiror specifically to hold the grid meghtiveuntilthe "positive peaker volt age overcomes the biasiand renders the tubecoirducting. The secondarywinding I53 would be connected totheigrid and holding anode circuits bf the oppositely-disposed tube of the two tube :groups oitube group-4 a manner understood by those skilled ln'the Jart.

In connecting theeignitor circuit 140 and the .g rid' circuit. Hi to the phase shifter 25, it is necessary to. determine phase of the anode voltage of the particular pair of tubes under con sfdeiration and l the-relation between the several transformer 144 may be an voltages of the respective electrodes of the tube. For the pair of tubes of tube group 4 illustrated. with the ignitor and grid circuits illustrated in diagrammatic detail, it will be assumed that the anode voltage has the phase position indicated by the arrow marked anode in the center of phase shift circuit 26. If the firing circuit voltage for the ignitor goes through zero at a given angle displaced from zero anode voltage, which we may assume for purposes of illustration is of the order of 140 degrees advance for the three-phase full wave connection illustrated, the firing reactor would cause the ignitor to fire at a point of the order of 30 degrees after the zero phase of anode voltage. Hence, the ignitor firing circuit I40 would be connected to taps on phase shifter 25 such that a line through the taps will be substantially parallel to a line advanced of the order of 140 degrees relative to thephase of the anode voltage shown. In the drawings, the tap connections indicated for the assumptions made are taps 50a and 5911.

If the grid peaker I55 is arranged to fire at the 65 point of the voltage impressed thereon, this means that the grid voltage goes through zero some 35 ahead of the zero phase of the anode voltage and the grid circuit MI is connected to taps 58a and 58a on the polygon windings 31 to 48 such that a line therethrough is advanced substantially 35 ahead of the assumed phase of the anode voltage. The arrangement and connection of the ignitor circuit I40 and the grid circuits I4 I of the tube groups 5 and 6 are made to phase shift network 26' in a similar manner to that described in connection with phase shift network 26.

The general operation of the illustrated embodiment of my invention may now be considered briefly. It was considered expedient to describe briefly the operation of the various component parts and elements in connection with the initial consideration of these elements so that the general overall operation may be more easily understood.

In the illustrated embodiment of the invention above described the system rectifies alternating current from the supply end, such as circuit I, by the tube groups 3 and 4 to direct current which traverses the direct loop comprising conductors 3a to 4b to the inverter tube groups 5 and where conversion is'effected to alternating current which is supplied to circuit 2. The direction of power flow is determined by the phase angle of grid excitation. Thus, if it is desired to transmit power from circuit I to circuit 2, all R switches associated with the apparatus of circuit I will be closed while all I switches at this rectifier end will be opened. Conversely, all I switches associated with the apparatus of circuit 2 at the inverter end will be closed while all R switches will be opened. With the amplidyne generators l9 and 19' operating, the induction regulator I09 will be adjusted to set the reference voltage Ea at such a value as to effect substantial equality between the rectifier voltage and the inverter counter voltage, so that no power is interchanged over the D.-C. loop. For this condition the amplidyne generator I9 will supply current to the phase shifter control windings I3 to 18 so that the rectifier grids are fully retarded as explained above and the inverter grids of the tube groups 5 and 6 are advanced by phase shifter 26' the minimum desired amount for a proper commutation angle as determined by the inverter bias resistor 13'. Power transfer from circuit I to circuit 2 is then increased by adjusting the induction regulator I09 at some predetermined setting corresponding to the desired load. The amplidyne generator I9 through the action of the control field Winding 8'6 will then decrease the energization of the phase shift control windin s I3 to I8 from full excitation in one direction which provides the 90 degree phase retard through zero to full excitation in the opposite direction for full grid advance or such excitation as will provide the necessary phase shift corresponding to the load setting previously set by regulator I09. If it be assumed that the load setting required full phase advance of the rectifier grids and the desired load was not yet attained, the load transfer mechanism would immediately function in response to a predetermined armature current of the amplidyne generator 19. If this armature current limit is exceeded, the voltage component derived from resistor 90, which is proportional to the armature current of amplidyne 19, would cause energization of field winding of the amplidyne '19- at the inverter end and cause the voltage of this amplidyne to change in such a direction as to change the saturation of control windings I3 to 18' of phase shifter 26' to change in such a direction as to effect a greater phase advance of the grids of the inverter tube groups 5 and 6. The advance of phase of the inverter tube groups reduces the counter E. M. F. of these tube groups and thus transfers load control to the inverter end. As a result, it has been found that increasing the inverter load angle, while holding the rectifier grids fixed, results in a larger load with an approximately constant margin angle. A similar sequence of operations would be effected if power transfer were in thereverse direction, namely from circuit 2 to circuit I.

- Now while the tube groups 3 and 4 were assumed to be operating as rectifiers, I also previously stated that the tube groups 5 and 6 were assumed to be operating as inverters with the I switches closed and the R switches open. Under inverter operation, the ignitor and grid circuits of these tubes are initially adjusted for the proper advanced phase shift for inverter operation. The phase adjuster 25', with the I switches closed, has a phase range of the order of 60 degrees. Aside from the feature of load transfer control effected through winding 85' the inverter tubes through the phase shifter 26' are responsive to four components of voltage, namely the reference voltage E's from adjustable contacts II8--I I9, a component of voltage dependent upon inverter unbalance, and, hence, derived from the negative phase sequence network I30, a component of voltage dependent upon the voltage of the circuit 2 derived from inverter bias resistor I29 and a component of voltage dependent upon the armature current of the amplidyne generator I9 derived from resistor One important feature of the control on the inverter grids is the relation between the amplidyne armature current and the reference voltage, When the reference voltage ER, which is also the reference voltage of the rectifier end, calls for a larger load, the control winding 88' is energized with a different current which acts through the phase shift control windings 3 to 18 to advance the inverter grids. In this way, the inverter grids are advanced to maintain an approximately constant margin angle or deionization angle. The two additional components of voltage provide correction for the inverter bias and phase unbalance in the inverter, if necessary, through modification of the excitacan 17? tion of Win -13 5 86; and hence-result in amber: shift. of the; inverter}. grids 12 eitectrlthei desired correction. Thetubeggroups 3; and: ilawhengopere ating as an inverter, operateiirrsubstantial mthe same manner as has been described for tube groupsi and 6. Load. transfer control from the tube groups 5 and 6 operating as rectifiers to tube groups 3 anddoperating'as inverters is effected through. armature current resistor iio' andg the load transfer circuit comprisingconductors, (3.5

1. In combination, a polyphase supply circuit" comprising a plurality of phase conductors, an output circuit comprising phase conductors, an inductive coupling for interconnecting said supply circuit and said output circuit and comprising a plurality'of windings connected to form a polygon, a plurality of other inductive windings inductively related to and interconnecting certain of said first mentioned windings for substantially fixing the voltages of said polygon in rigid polyphase relation, means including a plurality of pairs of variable impedance devices having end terminals and an intermediate junction terminal for each pair, said junction terminals being connected to different phase conductors of one of said circuits, means for connecting the end terminals of each pair of impedance devices to different pairs of spaced points on said polygon of windings, means for connecting the phase conductors of the other of said circuits to said polygon of windings, and means comprising a single source of variable voltage for inversely changing the impedance values of the respective impedances of each pair of impedances for changing the phase relation between the voltages of said supply circuit and said output circuit.

2. In combination, a polyphase supply circuit comprising a plurality of phase conductors, a plu e rality of output circuits, an inductive coupling 1 reluctance saldasupplyscircuit "and; said output "c r uits.v

.; eomb na'tienawpolyphasesimply circuit air mtsaz nin c iye' couplin iemiutereonpectim said: spra n circu t and ai i Bis-creative rcuitsandcomnrisin a l rahtvio .windirsseconnesitedto ierm aipo reon.

t e!induct i'eawin inss, inducterconne tins c rta n, 50 indu g ion substantial y the ydltcseszoizsaidm rson in r id Em yphase:relationsaioluralitxiptimirsioi-impedance ewinsiinesaawhi rsaclr-ne rrisnmvided withI e terminals and an intermediate junction terminal and arranged one pair of impedance windings for each phase conductor of said supply circuit, a

I plurality of presaturating windings arranged one with each of said impedance windings and connected in additive relation, a plurality of control saturating windings arranged one with each of said impedance windings and arranged in opposed relation for each pair of impedance windings, a first group of a plurality of pairs of terminals spaced a predetermined number of electrical degrees on said polygon of windings with each pair of terminals spaced the same number of terminals of said first group of terminals,

means for connecting each phase conductor of said supply circuit to a different junction terminal of said pairs of impedance winding means for selectively connecting the end terminals of each pair of impedance terminals to different pairs of spaced terminals of said first groups of spaced terminals or to different pairs of spaced terminals of said second group of spaced terminals, a source of constant unidirectional current connected to energize said presaturating windings, and a dynamo-electric machine having an armature current variable in magnitude and reversible in direction for energizing said control saturating windings in a manner to shift the voltage between said supply circuit and said output circuits within limits corresponding to the electrical degrees displacement between the terminals on said polygon of windings to which the rality of windings connected to form a polygon, a

plurality of other inductive windings inductively related to and interconnecting certain of said first mentioned windings for substantially fixing the voltages of said polygon in rigid polyphase relation, a plurality of pairs of variable impedance devices having end terminals and an intermediate junction terminal for each pair and arranged one pair of impedance devices for each phase conductor of said supply circuit, means for connecting each phase conductor of said supply circuit to a different junction terminal of the respective pairs of impedance devices, means for connecting the end terminals of each pair of impedance devices to difierent pairs of spaced points on said polygon of windings, means for connecting the phase conductors of said output circuit to said polygon of windings, and means comprising a single variable voltage generator for inversely changing the impedance values of the respective impedances of each pair of impedances for shifting the phase relation between the phase conductors of said supply circuit are connected.

4. In combination, a three phase supply circuit comprising three phase conductors, a polyphase output circuit comprising a plurality of phase conductors equal in number to a multiple of the v rality of circuits having voltage components res number of supply con-ductors for providing a pluspectively displaced in phase a predetermined and fixed number of electrical degrees, an inductive coupling for interconnecting said supply circuit and said output circuit and comprising a plurality of windings equal in number to the number of phases of said polyphase output circuit and connected to form a polygon having a plurality of connection points, a plurality of other inductive windings inductively related to and interconnecting diiferent vertices of said polygon of windings for substantially fixing the voltages of said polygon in rigid polyphase relation, means including saturable inductive windings for connecting each phase conductor to different pairs of connection points on said polygon of windings with the respective points of each pair displaced value in one direction through zero to a predetermined maximum value in the opposite direction so as to shift the phase relation between the voltage of said supply circuit and said output circuit an amount substantially equal to the num ber of electrical degrees between a pair or points on said polygon of windings.

BURNICE D. BEDFORD.

REFERENCES CITED The following references are of record in the 10 file of this patent:

UNITED STATES PATENTS Name Date Herskind Oct. 15, 1940 Number Certificate of Correction Patent No. 2,435,189. February 3, 1948.

BURNICE D. BEDFORD It is hereby certified that errors appear in the printed specification of the above numbered patent requiring correction as follows: Column 3, line 19, for the Word ignition read ignitron; column 9, line 39, for rectifier 7 3 read rectifier 78p; column 18,- line 39, for groups read group; and that the said Letters Patent should be read with these corrections therein that the same may conform to the record of the case in the Patent Oflice.

Signed and sealed this 25th day of May, A. D. 1948.

THOMAS E. MURPHY:

wtm omni i n f Pat Certificate of Correction Patent No. 2,435,189. February 3, 1948.

BURNIOE D. BEDFORD It is hereby certified that errors appear in the printed specification of the above numbered patent requiring correction as follows: Column 3, line 19, for the Word ignition read ignitron; column 9, line 39, for rectifier 73 read rectifier 73p; column 18,- line 39, for groups read group; and that the said Letters Patent should be read with these corrections therein that the same may conform to the record of the case in the Patent Ofiice.

Signed and sealed this 25th day of May, A. D. 1948.

THOMAS F.- MURPHY,

Assg'stant Qo mmgss z'orqer of Patents. 

